SSC JE Electrical 2018 with solution SET-1

An AC or DC generator requires direct current to energize its magnetic field. The DC field current is obtained from a separate source called an exciter. Either rotating or static-type exciters are used for AC power generation systems. There are two types of rotating exciters: brush and brushless. The primary difference between brush and brushless exciters is the method used to transfer DC exciting current to the generator fields. Static excitation for the generator fields is provided in several forms including field-flash voltage from storage batteries and voltage from a system of solid-state components. DC generators are either separately excited or self-excited.
EXCITATION SYSTEMS in current use include direct-connected or gear-connected shaft-driven DC generators, belt-driven or separate prime mover or motor-driven DC generators, and DC supplied through static rectifiers.
Static Excitation System
As the name indicates, all the components in this type of excitation system are static. A set of rectifiers is fed from a transformer that steps down the main generator or auxiliary bus voltage. The rectifiers supply the main generator excitation current directly through slip rings and they may be controlled or uncontrolled.
 
An external source of DC is necessary for the initial excitation of the field windings. On engine-driven generators, the initial excitation may be obtained from the storage batteries used to start the engine or from control voltage at the switchgear.
The main advantage of the static exciter is improved response as the field current is controlled directly by the thyristor rectifier but, of course, if the generator terminal voltage is depressed too low then excitation power will be lost. It is again possible to provide the power supply from both voltage and current transformers at the generator terminals but it is doubtful whether the improved response of the static exciter over a permanent magnet brushless scheme can be justified for many small embedded generators.
 

The dc shunt motor has a speed regulation of 5-10%, and hence, it is used for constant-speed drives like pumps, blowers, fans, etc. Though induction motors are preferable in these applications, the dc shunt motor is cheaper for low-speed drives. When the driven load requires a wide range of speed control, both below and above-rated speed, a dc shunt motor is employed, e.g. in lathes and other machining Tools. These motors are widely used in steel and aluminum rolling mills and the Ward Leonard speed control system.

In dc machine the field coils or field winding is excited by the current in order to produce the magnetic flux. In a DC shunt machine, the speed is Directly proportional to the back EMF and Inversely proportional to the flux.
N ∝ Eb/φ
Now if the field winding gets open than flux will become zero i.e φ = 0
∴ N ∝ Eb/0 
or
N = ∞
Hence the speed of the DC shunt Motor will attain the dangerous High Seed.
 
If the main field of a shunt motor or a compound motor is extremely weakened or if there is the complete loss of main field excitation, a serious damage to the motor can occur under certain conditions of operation.
Since the speed of a dc motor is inversely proportional to flux, its speed tends to rise rapidly when the flux is decreased. If the field failure occurs on a motor which is coupled to a load, which can neither be removed nor be reduced to a very low value, the residual flux due to the open field will develop a torque which will not be able to sustain rotation. Thus the motor will stall, heavy current will be drawn from the mains and the overload relay will trip.
On the other hand if field failure failure on an unloaded motor or if the application is such that it permits the motor to be unloaded or overhauled as in the ease of a hoist, the motor will not stall but instead its armature will accelerate quickly to a mechanically dangerous high speed or there will be destructive commutation. To prevent the above situation of over speeding, a field failure relay is used.
 

Energy in a Magnetic Field of inductance
The magnetic flux of the current in inductance is the electric energy supplied by the voltage source producing the current. The energy is stored in the magnetic field since it can do the work of producing the induced voltage when the flux moves. The amount of electric energy stored is
Energy = ½LI2 joule
Given
Inductance H = 0.4Current I = 2A
E = ½ × 0.4 × 22
E = 0.8 Joule

All split-phase motors have a start and run winding. The start windings must be disconnected from the circuit within a very short period of time or they will overheat. Several methods are used to disconnect the start windings. The centrifugal switch is the most common method in open motors; however, electronic start switches are sometimes used.
The centrifugal switch is used to disconnect the start winding from the circuit when the motor reaches approximately 75% of the rated speed. 
A centrifugal switch is a mechanical device attached to the end of the shaft with weights that will sling outward when the motor reaches approximately 75% speed. For example, if the motor has a rated speed of 1725 rpm, the centrifugal weights will change position at 1294 r.p.m (1725 x 0.75) and open a switch to remove the start winding from the circuit. This switch is under a fairly large current load, so a spark will occur.
If the switch fails to open its contacts and remove the start winding, the motor will draw too much current, and the overload device will cause it to stop. When the motor is de-energized, it will slow down and the centrifugal switch will close its contacts in preparation for the next motor starting attempt. The more the switch is used, the more its contacts will burn from the arc. If this type of motor is started many times, the first thing that will likely fail is the centrifugal switch. This switch makes an audible sound when the motor starts and stops.
Hence if the starting switch fails to open when needed, the starting winding mill almost always overheats and burns out.